KR0154711B1 - Power saving device of printer by power off mode - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a power saving apparatus of a printer system in a power off mode.

2. The technical problem to be solved by the invention

An object of the present invention is to interrupt the operation of the power supply means when the printer system is kept in the standby state for a predetermined time or when the power-off command signal is received from the external data input means, to cut off the power supplied to each part of the printer system It is to provide a power saving device that can minimize the power consumed in the standby state.

3. Summary of Solution to Invention

According to the present invention, when the control means of the printer system receives the power-off command signal in the logic state from the external data input means connected to the printer system, the control means applies the power-off signal in the logic state to the power control means. The power control means generates and applies a power control signal in a logic state for controlling the power supply means in response to a power off signal in a logic state applied from the control means. According to the logic state of the power control signal applied to the power supply means, the power supply means is shut down to cut off the power supplied to each part of the printer system. On the other hand, when a power restore signal in a logic state is applied to the power control means by a switch operation of a key switch provided in a user interface, the power control means generates a power control signal corresponding to the logic state of the power restore signal to generate the power. The operation of the supply means is resumed.

4. Important uses of the invention

It can be used in an image forming apparatus such as a printer, a copier, and the like.

Description

Power saving device of printer by power off mode

1 is a typical power distribution diagram in the printing mode of the printer.

2 is a power distribution diagram in the power saving mode of the printer.

3 is a block diagram of a power saving apparatus according to an embodiment of the present invention.

4 is a detailed circuit diagram of FIG.

5 is another detailed circuit diagram of the auxiliary power supply of FIG.

6 is a flowchart illustrating a power off signal generation process of a video controller according to an embodiment of the present invention.

The present invention relates to a power saving device for a printer, and more particularly, to a power saving device capable of minimizing power consumed by a printer in a standby mode.

Generally, a power saving device is a unit that consumes high power when an image forming apparatus such as a laser beam printer or a copier is in a standby state for a predetermined time (for example, a heat lamp). It refers to a device that saves power consumed by cutting off the power applied to the device. The power saving devices are constantly being researched and developed along with the development of new energy sources as a means for lowering the power consumption rate, which is increasing in the modern industrial society. Power saving devices used in conventional printers and computer peripherals automatically switch the power saving mode from the normal state to the power saving mode when the devices are kept in the standby state for a predetermined time or more. As a result, power applied to high-power units (eg, heat lamps, mechanical drives, etc.) has been cut off, thus saving power consumed in standby.

1 is a power distribution diagram supplied to each part of the printer system from a well-known multi-output switching mode power supply (SMPS) 100 which performs a switching mode regulating operation which is a power saving device in a printing mode of a printer. It is shown. Referring to FIG. 1, the SMPS 100 of the printer system receives AC commercial power ACin and rectifies it to DC power through a rectifier circuit. Thereafter, operation power (V1-V5) required for driving the printer system is generated and supplied to each unit 200-800 of the printer system. For example, in the printing mode, the SMPS 100 supplies an operating power source V3 necessary to drive a motor and a clutch for driving various rollers (for example, a feed roller, a discharge roller, etc.) of the printer. ). In addition, in the printing mode, an operating power source V5 necessary for fixing the developer transferred onto the paper is supplied to the fixing unit (eg, the heat lamp) 700. As described above, the SMPS 100, which is a power supply device in the printing mode, supplies the operating power V1-V5 to each of the sections 200-700 under the control of the printer control means.

2 shows a power distribution diagram supplied from the SMPS 100 to the printer system in the power saving mode of the printer. Referring to FIG. 2, when the printer system is in a power saving mode, only the media controller 200 and the engine control unit 300 of the printer are supplied with the operating power V1 from the SMPS 100, which is a power saving device. . It wakes up the printer system in power saving mode by inputting data from an external data input device (not shown) connected to the printer or checking key access from the OPE 800 which is a user interface means. To wake-up. That is, in the conventional printer, the SMPS 100 always consumes power unnecessarily by supplying the operating power V1 to the video controller 200 and the engine control unit 300 to wake up the printer system which is in the power saving mode. There was this.

Accordingly, it is an object of the present invention to provide a power saving apparatus capable of minimizing power consumption of a printer system in a standby state by switching a power mode of a printer system to a power off mode.

Still another object of the present invention is to provide a power saving device capable of minimizing power consumption of a printer system by automatically switching the power mode of the printer system to a power off mode when the printer system is maintained in a standby state for a predetermined time or more.

In accordance with another aspect of the present invention, there is provided a printer system connected to an external data input unit, wherein a power off command signal for switching a power mode of the printer system to a power off mode is received in response to a logic state. Control means for generating a power-off signal, main power supply means for generating an operating power for each part of the printer system by inputting AC commercial power, and supplying to each part of the printer system, and the power mode of the printer system is powered off In the mode, the user interface means for generating a power restore signal in a logic state for waking up the main power supply means, and the operation of the main power supply means in response to the logic state of the power off signal applied from the control means. It generates a power control signal of a logic state to shut off, and the user interface The power control means for generating a power control signal in a logic state for resuming the operation of the main power supply means; and the power control means and the user by inputting AC commercial power; Characterized in that the auxiliary power supply means for generating and supplying the operating power of the interface means at all times.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should also be noted that the same elements in the figures represent the same signs wherever possible. Also, in the following description, specific details such as specific circuit configurations and components are shown to provide a more general understanding of the invention. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details.

Figure 3 shows a block diagram of the previous month-saving device according to the present invention. Referring to FIG. 3, the SMPS 100, which is a main power supply, generates an operating power V1 of the video controller 200 as an input of AC commercial power ACin and supplies it to the video controller 200. The video controller 200 has a logic state power off signal corresponding to a power off command signal (hereinafter referred to as POCS) received from an external data input means (not shown). Is generated and output to the power control unit 160. The power control unit 160 corresponds to a logic state of the power-off signal POS received from the video controller 200, and a power control signal of a logic state for blocking the operation of the SMPS 100 (hereinafter referred to as a PCS). Generate the PCS and output it to the SMPS (100). The auxiliary power supply unit 170 inputs AC use power ACin to generate Voff, which is an operating power of the power control unit 160 and the user interface 900, and supplies it to the power control unit 160 and the user interface 900. . When the power mode of the printer system is the power off mode, the user interface 900 generates a power recovery signal (PRS) PRS in a logic state in response to a kissing switching for wake-up of the printer system. And output to the power control unit 160.

4 is a detailed circuit diagram of FIG. 3 according to an embodiment of the present invention. In FIG. 4, the SMPS 100, which is a main power supply means, is an example of generating operating powers V1 and V2 having two different voltages. It can also generate operating power. The power input unit 102 inputs the AC commercial power ACin, and the rectifier circuit 104 rectifies it. It is applied to the power supply terminal Vcc of the pulse width modulation (PWM) controller 106 via the rectified DC power supply starting resistor R1 and to the primary side of the transformer T1. The PUM controller 106 generates a PWM signal and applies it to the switching unit 108 through the output terminal OUT. The switching unit 108 switches the primary side of the transformer T1 by a PWM signal. Power is induced on the secondary side of the transformer T1 by the switching operation of the switching unit 108, and the induced power is rectified and smoothed through the first and second output rectifier circuits 110 and 112, and then the video controller. Are supplied to the operating power sources V1 and V2 of the 200 and the main body circuit 114, respectively. The operating power source V1 output from the first output rectifying circuit 110 is used as the operating power source of the video controller 200, the engine controller (not shown), and the digital circuit. The operating power supply V2 output from the output rectifying circuit 112 in FIG. 2 is a high voltage power supply and is used as an operating power supply for an analog circuit that requires a high voltage in the main body circuit 114 (for example, a developing unit). The diode D1 and the capacitor C1 are connected in series with the start winding of the transformer T1, and the connection point of the diode D1 and the capacitor C1 is connected to the power supply terminal Vcc of the PWM controller 106. Operation power is supplied to the PWM controller 106.

The auxiliary power supply unit 170 is composed of a transformer T2, a diode D2, and a capacitor C2. The primary side and the secondary side of the transformer T2 each have a turns ratio for generating the operating power Voff of the power control unit 160 and the user interface 900, and at the input terminal of the power input unit 102 and the anode of the diode D2, respectively. Connected. The diode D2 having the cathode connected to the power terminal Vcc of the flip-flop 162 of the power control unit 160 half-wave rectifies the AC power generated at the secondary side of the transformer T2. The capacitor C2 connected between the cathode of the diode D2 and the ground smoothes the half-wave rectified DC power Voff through the diode D2.

The power controller 160 includes a transistor Q1 and a flip-flop 162 having a terminal connected to the terminal COMP of the PWM controller 106 of the SMPS 100 and an emitter connected to the ground. The output terminal Q of the flip-flop 162 is connected to the base of the transistor Q1 and has a set bar ( Terminal and Clear Bar The terminal is connected to the user interface 900 and the video controller 200, respectively. In addition, the flip-flop 162 generates a power control signal PCS in a logic state for controlling the SMPS 100, which is a power supply device, using Voff output from the auxiliary power supply unit 170 as an operating power source through a power input terminal Vcc. do.

The video controller 200 generates a power-off signal POS in a logic state for controlling the operation of the power-control unit 160 in response to the power-off command signal POCS received from an external data input unit to clear the power-control unit 160. bar( Output to terminal

The user interface 900 is a set bar of the flip-flop 162 ( A key switch Ksw connected between the terminal and the ground, and a resistor R2 connected between the output terminal of the auxiliary power supply unit 170 and the key switch Ksw. The user interface 900 generates a power recovery signal PRS for a wake-up of the printer system in the power-off mode by switching the key switch Ksw, and sets the set bar of the flip-flop 162. Output to terminal

Hereinafter, the operation example of FIG. 4 according to the present invention will be described in detail.

First, in a printer system connected to an external data input unit and receiving predetermined image data and printing the image data on the paper, the video controller 200 changes the power mode of the current printer system from the external data input unit to the power-off mode. Check whether a power-off command signal POCS is received to command the switch. The video controller 200 generates a clear bar of the flip-flop 162 in response to the power-off command signal POCS being received in a logic low. Outputs the power-off signal POS, which is logic low, to the terminal. Clear bar of flip-flop 162 ( Power supply signal PCS, which is logic low, is applied to the base of transistor Q1 at the output terminal Q of the flip-flop 162 by applying a logic low power-off signal POS to the terminal. do. Accordingly, since the terminal COMP of the PWM controller 106 is grounded, the PWM controller 106 is shut down to block generation of the PWM signal. As the PWM signal is not generated in the PWM controller 106, the generation of the power supplies V1 and V2 is stopped in the first degree output rectifying circuit and the second degree output rectifying circuit 110 and 112. Therefore, the printer system can prevent unnecessary power consumption by cutting off the power supply by the power off command signal POCS received from the external data input means, and the power mode of the printer system is referred to as the power off mode. In addition, the power off mode is maintained until the transistor Q1 is turned off. On the contrary, a process for waking up the printer system in the power off mode will be described in detail with reference to FIG. The auxiliary power supply unit 170 decompresses, rectifies and smoothes the AC commercial power ACin using the transformer T2, the diode D2, and the capacitor C2, and then operates the flip-flop 162 and the user interface 900 to operate the power Voff. Outputs The power supply Voff output from the auxiliary power supply unit 170 has a set bar of the flip-flop 162 with the voltage level high through the resistor R2. Is applied to the power supply terminal Vcc of the flip-flop 162. When the user presses the key switch Ksw provided in the user interface 900 to wake up the printer system in the power-off mode, the power Voff applied from the auxiliary power supply unit 170 becomes a resistor R2 and the key switch. It is grounded through (Ksw). Therefore, the set bar of the flip-flop 162 ( The logic of the power restore signal PRS applied to the < RTI ID = 0.0 > terminal < / RTI > As a result, the power control signal PCS output from the output terminal Q of the flip-flop 162 is applied to the base of the transistor Q1 in a logic high state, thereby turning off the transistor Q1. As the transistor Q1 is turned off, the PWM controller 106 normally generates a PWM signal to resume the operation of the SMPS 100. Accordingly, the video controller 200 and the main body circuit 114 receive operating powers V1 and V2 from the first degree output rectifying circuit 110 and the second degree output rectifying circuit 112, respectively, and the power mode of the printer system is normal. The mode is switched. As described above, the power-up mode of the printer system may be switched to the normal mode by waking up the printer system in the power-off mode through the user interface 900.

FIG. 5 is a detailed circuit diagram of another embodiment of the auxiliary power supply unit 170 of FIG. 3. Referring to FIG. 5, the configurations of the SMPS 100, the power controller 160, and the user interface 900 are the same as those of FIG. 4 described above, and the output stages of the first degree output rectifying circuit 110 of the SMPS 100 are different from each other. It consists of a diode D3 for the purpose of preventing reverse current connected directly between grounds, a resistor R3, and a rechargeable battery (hereinafter referred to as RB).

Hereinafter, an operation example of the present invention will be described in detail with reference to FIG. 5.

First, in a printer system connected to an external data input unit and receiving predetermined image data and printing the image data on a paper, the rechargeable battery RB may be configured in the SMPS 100 when the power mode of the printer system is a normal mode. Charged to a constant voltage level Voff by the operating power supply V1 output from the 1-degree output rectifier circuit 110. After the rechargeable battery RB is fully charged, the operating power V1 output from the first-degree output rectifying circuit 110 is applied at a voltage level high to the power terminal Vcc of the flip-flop 162 through the diode D3. . In addition, the operating power supply V1 is a set bar of the flip-flop 162 through the resistor R2 of the user interface 900. ) Is applied at power level high. If the video controller 200 receives the power-off command signal POCS in the logic low state from the external data input unit, the video controller 200 in response to the flip-flop 162 clear bar ( Outputs the power-off signal POS in a logic low state to the terminal. Clear bar of flip-flop 162 ( Power supply signal PCS in the logic low state is applied to the base of the transistor Q1 in the output terminal Q of the flip-flop 162 by applying the power-off signal POS in the logic low state to the terminal Q1. Is turned on. Accordingly, as the terminal COMP of the PWM controller 106 is grounded, the PWM controller 106 is shut down to block generation of the PWM signal. When the PWM controller 106 does not generate a PWM signal, the first-degree output rectifying circuit and the second-degree output rectifying circuit 110 and 112 stop generating power V1 and V2, and the printer system enters the power-off mode. Is switched. When the power mode of the printer system is the power off mode, the set bar of the flip-flop 162 ( The power off mode is maintained by applying a voltage level high to the terminal and the power supply terminal Vcc by the charging voltage Voff of the rechargeable battery RB. On the other hand, when the user presses the key switch Ksw provided in the user interface 900 to wake up the printer system which is in the power-off mode, the power Voff applied from the auxiliary power supply unit 170 resists R2 and kisses. It is grounded through position Ksw. Therefore, the set bar of the flip-flop 162 ( The power recovery signal PRS applied to the terminal is in a logic low state to set the flip-flop 162. As a result, the power supply control signal PCS output from the output terminal Q of the flip-flop 162 is applied to the base of the transistor Q1 at a logic state high, thereby turning off the transistor Q1. As the transistor Q1 is turned off, the PWM controller 106 normally generates a PWM signal to resume the operation of the SMPS 100. Accordingly, the video controller 200 and the main body 114 receive operating power V1 and V2 from the first degree output rectifying circuit 110 and the second degree output rectifying circuit 112, respectively. Recharged. As described above, the power-up mode of the printer system may be switched to the normal mode by waking up the printer system in the power-off mode through the user interface 900.

6 illustrates a process in which the video controller 200 generates a power-off signal POS for automatically switching the power mode of the printer system to the power-off mode when the print system is in the standby mode for a predetermined time. 4 and 5 illustrate that the video controller 200 generates a power-off signal POS in a logic state in response to the power-off command signal POCS from an external data input unit. In the following description, a process of generating a power-off signal POS by the control program included in the video controller 200 will be described.

First, as the power of the printer system is turned on, the video controller 200 performs an initialization process for normal operation of the system in step 902 and then proceeds to step 904. In operation 904, the video controller 200 counts a time when the printer system is in a standby state. In operation 906, the video controller 200 compares the counted value with the reference value set by the user's selection in operation 904. If the counting value is smaller than the reference value in step 906, the video controller 200 returns to step 904 to continue counting the waiting time. If the counting value is greater than or equal to the reference value set by the user in step 906, the video controller 200 outputs the power-off signal POS to block the output voltage of the SMPS 100, which is a power supply, in a logic low state. do. The power off signal POS of the logic low state generated from the video controller 200 through steps 902-908 blocks the operation of the SMPS 100 as in the above-described embodiments of FIGS. 4 and 5. Switch to the power off mode. Thereafter, as the operation of the SMPS 100 is restarted by the switching operation of the key switch Ksw from the user interface 900, the power mode of the printer system is changed to the normal mode.

As described above, the present invention provides the power supply to each part of the printer system when the printer system is kept in the standby state for a predetermined time or more, or when the power-off command is received from the external data input means by the user's selection. By cutting off the power supply, there is an advantage that the power consumption of the printer system in the standby mode can be minimized.

Meanwhile, in the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. For example, when the power mode of the current printer system is to be switched to the power off mode, a power off mode selection switch may be provided in the user interface to switch the power mode of the printer system to the power off mode.

Claims (4)

A power saving apparatus of a printer system connected to an external data input means, comprising: multi-output power supply means for generating and supplying operating power to each part of the printer system from an AC commercial power source, and a power control means and a user interface means from an AC power supply. Auxiliary power supply means for generating and supplying operating power at all times; and in response to a power off command signal indicating a power off mode from the external data input means when the power mode of the printer system is in the normal mode. A switching means for generating a power-off signal of the power supply and outputting the power-off signal to the power supply control means; and a key switch provided to wake up the multi-output power supply means when the power supply mode of the printer system is the power-off mode. In response to the power supply control means A user interface means for outputting a call and an operation of the multi-output power supply means in response to a logic state of a power off signal applied from the control means to switch the power mode of the printer system to the power off mode and A power control means for generating a power control signal in a logic state for resuming the operation of the multi-output power supply means in response to a logic state of a power restore signal applied from an interface means to restore the power mode of the printer system to a normal mode; Power saving device for a printer system, characterized in that configured. A power saving device of a printer system connected to an external data input means, comprising: multi-output power supply means for generating and supplying operating power of each part of the printer system from an AC commercial power source; and when the power mode of the printer system is a normal mode, Connected between the multi-output power supply means and the ground and charged to a constant voltage level by the digital circuit operating power output from the multi-output power supply means, and at the moment when the power-off mode of the printer system is switched to the power-off mode, Auxiliary power supply means for supplying operating power to the power control means and the user interface means for wake-up; and a power-off command indicating a power-off mode from the external data input means when the power mode of the printer system is the ortho mode; In response to a signal being received, Control means for generating a one-off signal and outputting it to the power control means; and in a switching operation of a key switch provided to wake up the multi-output power supply means when the power mode of the printer system is the power off mode. Responsive to the user interface for outputting a power restore signal in a logical state to the power control means, and in response to a logic state of a power off signal applied to the control step, blocking the operation of the multi-output power supply means. A logic state of switching the power mode to the power off mode and resuming the operation of the multi-output power supply means in response to the logic state of the power restore signal applied from the user interface to restore the power mode of the printer system to the ortho mode. Characterized by consisting of a power control means for generating a power control signal. Power-saving devices of the printer system. The method of claim 2, wherein the auxiliary power supply means is an anode connected to the output terminal of the multi-output power supply means to perform a reverse current prevention function, and connected between the cathode and the ground of the diode at a constant voltage level Power saving device for a printer system, characterized in that consisting of a rechargeable battery to be charged. In the power saving device of the printer system connected to the external data input means, the multi output power supply means for generating and supplying the operating power of each part of the printer system from the AC power supply, and the operating power of the power control means and the user interface from the AC commercial power supply. And auxiliary power supply means for always supplying and supplying power, and when the power mode of the printer system is in the normal mode, the power supply mode of the printer system is switched to the power off mode in response to the printer system not being used for a predetermined time. A control means for generating a power-off signal for outputting the power-off signal to the power control means, and a switching operation of a key switch provided to wake up the multi-output power supply means when the power mode of the printer system is the power-off mode. In response to the transfer of the logic state to the power supply control means. A user interface for outputting an original restoration signal and an operation of the multi-output power supply means in response to a logic state of a power off signal applied from the control means to switch the power mode of the printer system to the power off mode; A power control means for generating a power control signal in a logic state for resuming the operation of the multi-output power supply means in response to a logic state of a power restore signal applied from a user interface to restore the power mode of the printer system to the ortho mode; Power saving device for a printer system, characterized in that made.